Characterisation of local immune responses induced by a novel nano-particle based carrier-adjuvant in sheep.

Most adjuvants require danger signals to promote immune responses against vaccine antigens. Our previous studies have characterised a powerful nano-particulate antigen delivery system, which by itself does not induce inflammation, and which further appears to induce substantial immune responses in mice and sheep without the requirement for added stimulators of toll like receptors or other pathogen recognition receptors. In the present study we dissect the nature of the early induction phase of the immune response stimulated by such a vaccine comprising 40 nm polystyrene nano-particles conjugated to the antigen. We analyse the kinetics of export from an individual draining lymph node from the sheep, of antibodies and cytokines as well as antigen responsive CD4 and CD8 T cells. Our results indicate that simple inert nano-bead based antigen delivery into the draining area of the lymph node is highly efficient at priming combined humoral and T cell antigen specific immunity without the need for added 'danger signals'. Furthermore this nano-bead adjuvant is a potent agent capable of promoting cross-priming for CD8 T cell induction in sheep. Interestingly, using nano-beads, similarly to what has been observed with natural pathogen based lymph node stimulation, a phase of CD4 T cell priming and export preceded CD8 T cell induction, suggesting the engagement of natural priming processes and kinetics.

Phenotypic analysis of ovine antigen presenting cells loaded with nanoparticles migrating from the site of vaccination.

Virus-sized particulate adjuvants such as ISCOMs, polystyrene nanoparticles and virus-like particles have been shown to target dendritic cells, resulting in the activation of T and B cells in vivo. Using an ovine pseudo-afferent lymph cannulation model to capture APC that traffic from the site of injection to the local lymph node, we show that 40-50 nm nanoparticles are taken up at the site of injection by dendritic cells (DCs) migrating to the draining lymph node. These DCs can express CD11c, CD1b, CD5, MHC class II and CD8. Nanoparticles transported by DCs migrating from the site of injection to the local lymph node therefore needs to be considered as a new mechanism underlying the immunogenicity of virus-sized vaccine delivery systems.

Systemic immune responses in sheep, induced by a novel nano-bead adjuvant.

Although a number of adjuvants are currently approved for use in veterinary species, only alum has been widely used in humans. While it induces strong antibody responses, cell mediated responses are often low and inflammatory reactions at the site of injection are common. We investigated the immunological properties of a novel nano-bead adjuvant in a sheep large-animal model. In contrast to alum, antigen covalently coupled to nano-beads induced substantial cell mediated responses along with moderate humoral responses. No adverse reactions were seen at the site of immunisation in the sheep. Thus, nano-bead adjuvants in veterinary species may be useful for the induction of immunity to viral pathogens, where a cell mediated response is required. These findings also highlight the potential usefulness of nano-bead vaccines for intracellular pathogens in humans.

Vaccines that facilitate antigen entry into dendritic cells.

Although vaccines have been highly successful in preventing and treating many infectious diseases (including smallpox, polio and diphtheria) diseases prevalent in the developing world such as malaria and HIV, that suppress the host immune system, require new, multiple strategies that will be defined by our growing understanding of specific immune activation. The definition of adjuvants, previously thought of as any substance that enhanced the immunogenicity of antigen, could now include soluble mediators and antigenic carriers that interact with surface molecules present on DC (e.g. LPS, Flt3L, heat shock protein) particulate antigens which are taken up by mechanisms available to APC but not other cell types (e.g. immunostimulatory complexes, latex, polystyrene particles) and viral/bacterial vectors that infect antigen presenting cells (e.g. vaccinia, lentivirus, adenovirus). These approaches, summarized herein, have shown potential in vaccinating against disease in animal models, and in some cases in humans. Of these, particle-antigen conjugates provide rapid formulation of the vaccine, easy storage and wide application, with both carrier and adjuvant functions that activate DC. Combined vaccines of the future could use adjuvants such as virus-like particles and particles targeted towards a predominant cellular type or immune response, with target cell activation enhanced by growth factors or maturation signals prior to, or during immunization. Collectively, these new additions to adjuvant technology provide opportunities for more specific immune regulation than previously available.

Size-dependent immunogenicity: therapeutic and protective properties of nano-vaccines against tumors.

Infection can protect against subsequent disease by induction of both humoral and cellular immunity, but inert protein-based vaccines are not as effective. In this study, we present a new vaccine design, with Ag covalently conjugated to solid core nano-beads of narrowly defined size (0.04-0.05 microm) that localize to dendritic cells (DEC205(+) CD40(+), CD86(+)) in draining lymph nodes, inducing high levels of IFN-gamma production (CD8 T cells: precursor frequencies 1/5000 to 1/1000) and high Ab titers in mice. Conjugation of Ag to these nano-beads induced responses that were significantly higher (2- to 10-fold) than those elicited by other bead sizes, and higher than a range of currently used adjuvants (alum, QuilA, monophosphoryl lipid A). Responses were comparable to CFA/IFA immunization for Abs and ex vivo peptide-pulsed dendritic cell immunization for CD8 T cells. A single dose of Ag-conjugated beads protected mice from tumors in two different model challenges and caused rapid clearance of established tumors in mice. Thus, a range of Ags conjugated to nano-beads was effective as immunogens in both therapeutic and prophylactic scenarios.

Delivery of a heterologous antigen by a registered Salmonella vaccine (STM1).

STM1 is an aro A(-) attenuated mutant of Salmonella enterica serovar Typhimurium, and is a well-characterised vaccine strain available to the livestock industry for the prevention of salmonellosis in chickens. This strain has potential for heterologous antigen delivery, and here we show that the strain can be used to deliver a model antigen, ovalbumin, to immune cells in vitro and in vivo. Two plasmid constructs expressing the ovalbumin gene were utilised, one of which uses a prokaryotic promoter and the other the CMV promoter (DNA vaccine). In vitro, STM1 carrying ovalbumin-encoding plasmids was able to invade dendritic cells and stimulate a CD8(+) cell line specific for the dominant ovalbumin epitope, SIINFEKL. In vivo, spleen cells were responsive to SIINFEKL after vaccination of mice with ovalbumin-encoding plasmids in STM1, and finally, humoral responses, including IgA, were induced after vaccination.